• Proceedings of the KIPE Conference
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• 2010.07a
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• pp.170-171
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• 2010

The power loss due to PV module mismatch in PV array system is analyzed and a mismatch compensation method is proposed. A dc-dc converter is used to compensate for series mismatch caused by a low current module in a string. The converter is controlled to maximize the array power output. The proposed compensation method was verified by PSpice simulation.

• Journal of the Korean Solar Energy Society
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• v.29 no.1
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• pp.58-63
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• 2009

In this paper, the power loss due to PV module mismatch in PV string is analyzed and a mismatch compensation method is proposed to improve the efficiency of PV system. The analysis of mismatch loss using PV model simulation reveals that the mismatch module may decrease the total efficiency because the MPPT function of power conditioner make the PV system operate at the local maximum point. The mismatch loss can be severe if the maximum power point current of mismatch module is less than that of string. The proposed compensation method which is simply implemented with a buck type converter shows the possibility to remove the mismatch loss. The effectiveness of the analysis and compensation method is verified by a prototype experiment.

• Journal of the Korean Solar Energy Society
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• v.32 no.3
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• pp.26-32
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• 2012

A current compensation method to reduce the mismatch loss in PV systems is proposed as a way to increase the power generation efficiency. A dc-dc converter is used to supply currents to irregular modules in a PV string and is powered from the string output. The converter's voltage conversion ratio is adjusted so that all the modules in the string are operated at the maximum power point. The power rating and size of the converter can be reduced since only the current difference between the regular and irregular module may be supplied. The compensated string shows very little voltage mismatch compared to other regular strings. The validity of the proposed method is verified through a simulation and experiments in a prototype PV system.

• Proceedings of the KIPE Conference
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• 2009.11a
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• pp.123-125
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• 2009

Mismatch of electrical characteristics of modules in PV string invokes mismatch power loss. The mismatch occurs due to various causes such as shadow, aging, contamination, and module exchange. The concept of mismatch compensation converter(MCC) is presented in this paper to remedy the mismatch loss problem. MCC is connected to irregular modules only. MCC is composed of dc-dc converter and MPPT controller. It is noted that MPPT algorithm is employed to control MCC and is effective for maximum power available from irregular modules. The selection guide of MPPT control period is given based on the period of MPPT in PCU. The effectiveness of the MCC is verified by a prototype experiment.

• Journal of the Korean Institute of Telematics and Electronics A
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• v.31A no.6
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• pp.98-106
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• 1994

To realize high accuracy and high speed we developed a new self compensation scheme and applied it to a 10-bit D/A converter. This circuit can compensate the device mismatch without interrupting the D/A converter operation. With the compensation circuit,INA decreased down to 0.22LSB from 0.47LSB. The device was fabricated using a 0.8$\mu$m CMOS process. The area of the D/A converter core is 3.2mm$^{2}$ and the area of the compensation part is 0.64mm$^{2}$.

• Journal of the Institute of Electronics Engineers of Korea SD
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• v.42 no.2 s.332
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• pp.1-8
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• 2005

An area-efficient DC-DC voltage up-converter in a poly-Si TFT technology for system-on-glass is described which provides low-ripple output. The voltage up-converter is composed of charge-pumping circuit, comparator with threshold voltage mismatch compensation, oscillator, buffer, and delay circuit for multi-phase clock generation. The low ripple output is obtained by multi-phase clocking without increasing neither clock frequency nor filtering capacitor The measurement results have shown that the ripple on the output voltage with 4-phase clocking is 123mV, while Dickson and conventional cross-coupled charge pump has 590mV and 215mV voltage ripple, respectively, for $Rout=100k\Omega$, Cout-100pF, and fclk=1MHz. The filtering capacitor required for 50mV ripple voltage is 1029pF and 575pF for Dickson and conventional cross-coupled structure, for Iout=100uA, and fclk=1MHz, while the proposed multi-phase clocking DC-DC converter with 4-phase and 6-phase clocking requires only 290pF and 157pF, respectively. The efficiency of conventional and the multi-phase clocking DC-DC converter with 4-phase clocking is $65.7\%\;and\;65.3\%$, respectively, while Dickson charge pump has $59\%$ efficiency.